The disclosed technology generally relates to operation modes for hearing devices. In some implementations, the disclosed technology includes a hearing device entering into and operating in an airplane mode or a mode of operation that limits communication with a select frequency or select group of frequencies. To enter a mode of operation, a user may use two inputs for the hearing device. For example, one input may be a battery closing and another input may include the pushing of a button on a device (e.g., on the hearing device or a mobile device in communication with the hearing device).

A bone conduction audio apparatus includes at least one ear hook assembly. A main circuit board is provided in the ear hook assembly. Each ear hook assembly includes an operating unit, a line concentrator and a bone conduction transducer. Each operating unit is electrically connected with corresponding line concentrator by contact springs or connecting wires, and connected with the main circuit board via the line concentrator. Each bone conduction transducer is electrically connected with the main circuit board via corresponding line concentrator. A controller of the main circuit board receives touch signals from all operating units to determine and initiate relating earphone operating. The bone conduction audio apparatus adopts bilateral triggering interaction mechanism. The line concentrator is combined with the suspended bone conduction transducer.

A method of manufacturing a faceplate for a hearing device, the faceplate configured to cover a lateral opening of a housing of the hearing device and having a side which is laterally oriented when the hearing device is worn at least partially in the ear canal, including the steps of: providing a faceplate base part including a first surface, a faceplate insertion part including a second surface, and a printed circuit board (“PCB”) with an antenna; inserting the antenna PCB into the faceplate base part so that that the antenna PCB extends along the first surface; inserting the faceplate insertion part into the faceplate base part so that the second surface of the faceplate insertion part pushes the antenna PCB against the first surface of the faceplate base part; and fixing the faceplate insertion part within the faceplate base part so as to form the faceplate.

The disclosure relates to a hearing aid for placement in an ear canal, the hearing aid having a proximal end and a distal end, the proximal end is inserted into the ear canal to face the tympanic membrane, the distal end is opposite. The hearing aid comprises a shell customized for the ear canal. The shell comprises an inner space configured for at least partly receiving a rechargeable battery, a charging arrangement, at least one microphone arrangement, and an integrated circuit. The hearing aid comprises a faceplate comprising an upper face and a lower face, the upper face being exposed at the distal end when the shell is placed in the user's ear canal. The faceplate is configured for closing the inner space, wherein the IC is arranged between the faceplate and the proximal end.

A hearing device includes an enclosure comprising a shell and a faceplate and is configured for at least partial insertion within an ear of a user. An antenna structure of the hearing device is oriented such that a direction of an electric field (E-field) of a propagating electromagnetic signal generated by the antenna structure is directed non-tangentially with respect to the user at the location of the user's ear. The antenna structure includes an antenna disposed in or on the faceplate and a ground plane at least partially supported by the faceplate. A battery and electronic circuitry are disposed within the shell. The electronic circuitry is powered by the battery and is electrically coupled to send and/or receive signals via the antenna structure.

An inductive charging case in accordance with certain embodiments presented herein comprises a base and a lid mechanically coupled together via a hinge mechanism. When the inductive charging case is in a closed arrangement (e.g., the lid is positioned adjacent to the base), the lid and base collectively define an interior volume that is configured to enclose an electronic device therein. The electronic device includes one or more rechargeable batteries, a receiver coil, and circuitry for recharging the one or more rechargeable batteries, while the inductive charging case includes inductive charging circuitry, including at least one inductive charging coil, that is configured to provide power to the electronic device which is then used to charge the one or more rechargeable batteries and/or power the electronic device.

A hearing aid comprises a housing, comprising: a substrate carrying a wireless interface, the substrate further carrying a processor, the substrate arranged in the housing; an antenna arranged in the housing, the antenna being connected to the wireless interface; the antenna configured to emit and/or receive electromagnetic fields, an electronic element, connected to the processor via an electrical connection line; wherein a decoupling element is provided in the electrical connection line wherein the decoupling element has a characteristic frequency at the frequency, at which the antenna is tuned to radiate and/or receive the electromagnetic fields.

A hearing instrument comprises a wireless communication unit interconnected with an antenna for emission and reception of an electromagnetic field having an RF wavelength, a speaker interconnected with the wireless communication unit and being configured to provide an output audio signal. A battery is configured to supply power to the hearing instrument and a filter circuit interconnects the battery and a power management circuit of the hearing instrument. The antenna extends from a feed and at least a part of the antenna being is arranged adjacent the battery. A distance between the at least part of the antenna and the battery is below 1/40 of the wavelength. The filter circuit is configured to de-couple the battery and the power management circuit at frequencies above 3 MHz and configured to connect the battery to the power management circuit at frequencies below 300 kHz.

Embodiments of the present invent include a method of controlling unwanted vibration in a tympanic lens, wherein the tympanic lens comprises a perimeter platform connected to a microactuator through at least one biasing element, the method comprising the step of: damping the motion of the at least one biasing element. In embodiments of the invention, the at least one biasing element is a spring. In embodiments of the invention, the at least one bias spring is coated in a damping material.

A hearing instrument charger device for charging an individually shaped hearing instrument, includes: a charger casing; a charger power supply within the charger casing; a first charger coil connected to the charger power supply; charger electronics for controlling charging of the hearing instrument; and a holder configured for receiving the hearing instrument, the holder located within the charger casing; wherein the holder for the hearing instrument has a shape that is specific for the individually shaped hearing instrument, such that when the individually shaped hearing instrument is received in the holder, a second charger coil of the individually shaped hearing instrument is in an operative position for receiving charging power from the first charger coil of the hearing instrument charger device.